Apparatus for housing a light assembly

ABSTRACT

An apparatus and related method for housing a light assembly apparatus includes a housing having a housing first end and a housing second end arranged along a central axis, the housing further includes a plurality of fins each having a fin first end and a fin second end, the plurality of fins forming a plurality of vents therebetween, each the plurality of fins has a curvature extending from the fin second end such that the plurality of fins converge towards the central axis proximate each fin first end, an endpiece proximate the housing first end and arranged proximate to the fin first end of each of the plurality of fins, the endpiece having a circular portion including a continuous circumference about the central axis, an electrical connector arranged proximate to the endpiece and arranged along the central axis, and a space arranged along the central axis proximate the housing second end and further configured with the plurality of fins and the plurality of vents arranged therearound, the space configured to, at least in part, house a light assembly. Other embodiments are disclosed as well.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §119(e) to provisionalU.S. Patent Application No. 60/988,954, filed on Nov. 19, 2007 and toprovisional U.S. Patent Application No. 61/096,273, filed on Sep. 11,2008, the disclosures of which are expressly incorporated by referenceherein in their entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention is directed generally to a method and device for thethermal management of heat in electronic devices. More particularly, theinvention is directed to thermal management of heat in electronicdevices having printed circuit boards that may include light emittingdiodes, or the like.

2. Related Art

Numerous electronic manufacturing techniques have attempted to deal withcomponent placement on printed circuit boards (PCB) to minimize costsfor producing electronic products. For many products, the types ofelectronic components involved may dictate particular layouts and theuse of special arrangements to minimize heat build-up in the circuitryand components during use. However, there tends to be a limit to theeffectiveness of the heat removal capabilities of current techniques,which might suppress progress in producing new products that have higherheat removal needs.

Accordingly, there is a need for a method and apparatus that providesimproved heat dissipation techniques for printed circuit boards ofvarious types so that components that produce more heat may beaccommodated, including those devices for producing visible light.

SUMMARY OF THE INVENTION

The invention meets the foregoing need and provides a method andapparatus for thermal management in electronic devices and thatfurthermore includes other advantages apparent from the discussionherein. Moreover, the invention is directed to a method and device forthermal management in electronic devices with printed circuit boards(PCB). The apparatus includes at least one PCB. The PCB defines a firstsurface and a second surface, and the PCB may include a metal layer anda core. The core may define a first core surface and a second coresurface. The metal layer may be secured to the first core surface. Theapparatus may include an electronics package, which may be secured tothe first surface of the PCB. The apparatus may include a plurality ofpins, each of which may have a first end and a second end. The pins maybe disposed about the PCB with the first ends generally proximate theelectronics package such that heat generated by the electronics packagemay be received by the pins generally proximate the first ends.Generally, the pins may pass through the core generally from the firstcore surface to the second core surface to conduct heat generated by theelectronics package through the core as heat is conducted from the firstend toward the second end of the pins. A second PCB may be spaced apartfrom the first PCB with the pins securing the first PCB to the secondPCB.

The invention may be implemented in a number of ways. According to oneaspect of the invention, a device for producing light is provided thatincludes a housing configured to receive a light producing assembly thatincludes at least one electronics package which generates heat, and aplurality of vents configured in the housing to permit an air flowthrough the housing to conduct the generated heat out of the housing,wherein the light producing assembly comprises a plurality of printedcircuit boards (PCBs) spaced at an interval and connected by a pluralityof pins, the plurality of pins being configured to conduct at least aportion of the generated heat from the at least one electronics packagemounted on at least one of the PCBs into the interval so that the airflow passes through the interval and out of the housing.

In another aspect, a device for producing light is provided thatincludes means for separating a plurality of printed circuit boards(PCBs) at an interval, each PCB including an electronics package,wherein one electronics package includes a plurality of light emittingdiodes (LEDs) for generating white light, means for receiving externalpower for powering each electronics package, means for venting at leasta portion of heat generated by at least one electronics package, andwherein at least a portion of the means for separating provideselectrical conductivity between the plurality of PCBs and providesthermal conductivity into the interval for dissipation by the means forventing.

Yet in another aspect of the invention, a device for producing light isprovided that includes first means for dissipating heat for a lightemitting diode (LCD) assembly having two printed circuit boards (PCBs)and for separating the two PCBs at an interval, a housing to house thefirst means for dissipating heat, wherein a second means for dissipatingheat is formed by the housing, wherein the first means for dissipatingis connected thermally proximate an electronics package on one of thePCBs.

In another aspect, an apparatus for a light is provided that includes ahousing having a circumference larger at a first end greater than asecond end and configured to receive a light assembly having two printedcircuit boards (PCBs) held apart at an interval by a plurality of pinsto convey heat generated by at least one PCB into the interval and aplurality of fins configured to create a plurality of vents in thehousing, the plurality of vents configured to be proximate the intervalfor permitting air flow into the housing and past the plurality of pinsfor conveying generated heat out of the housing.

In another aspect, a method of providing a lighting device includesproviding a housing configured to receive a light producing assemblythat includes at least one electronics package that generates heat andproviding a plurality of vents configured in the housing to permit anair flow through the housing to conduct the generated heat out of thehousing, providing a plurality of printed circuit boards (PCBs) spacedat an interval and connected by a plurality of pins, the plurality ofpins being configured to conduct at least a portion of the generatedheat from the at least one electronics package mounted on at least oneof the PCBs into the interval so that the air flow passes through theinterval and out of the housing.

In another aspect, an apparatus for a light assembly includes a housingincluding a housing first end and a housing second end arranged along acentral axis, the housing further including a plurality of fins eachhaving a fin first end and a fin second end, the plurality of finsforming a plurality of vents therebetween, each the plurality of finshas a curvature extending from the fin second end such that theplurality of fins converge towards the central axis proximate each finfirst end, an endpiece proximate the housing first end and arrangedproximate to the fin first end of each of the plurality of fins, theendpiece having a circular portion comprising a continuous circumferenceabout the central axis, an electrical connector arranged proximate tothe endpiece and arranged along the central axis and a space arrangedalong the central axis proximate the housing second end and furtherconfigured with the plurality of fins and the plurality of ventsarranged therearound, the space configured to, at least in part, house alight assembly.

In yet another aspect, a light assembly apparatus includes a housingincluding a housing first end and a housing second end arranged along acentral axis, the housing further includes a plurality of fins eachhaving a fin first end and a fin second end, the plurality of finsforming a plurality of vents therebetween, each the plurality of finsbeing arranged substantially symmetrically about the central axis, anendpiece proximate the housing first end and arranged proximate to thefin first end of each of the plurality of fins, the endpiece having acircular portion comprising a continuous circumference about the centralaxis, an electrical connector arranged proximate to the endpiece andarranged along the central axis and a space arranged along the centralaxis proximate the housing second end and further configured with theplurality of fins and the plurality of vents arranged therearound, thespace configured to, at least in part, house a light assembly.

In another aspect, a method for configuring a light assembly includesproviding a housing having a first end and a housing second end andarranged along a central axis, providing a plurality of fins each havinga fin first end and a fin second end, the plurality of fins forming aplurality of vents therebetween, each the plurality of fins has acurvature extending from the fin second end such that the plurality offins converge towards the central axis proximate each fin first end,providing an endpiece proximate the housing first end and arrangedproximate to the fin first end of each of the plurality of fins, theendpiece having a circular portion comprising a continuous circumferenceabout the central axis, providing an electrical connector arrangedproximate to the endpiece and providing a space arranged along thecentral axis proximate the housing second end and further configuredwith the plurality of fins and the plurality of vents arrangedtherearound, the space configured to, at least in part, house a lightassembly.

Additional features, advantages, and embodiments of the invention may beset forth or apparent from consideration of the following detaileddescription, drawings, and claims. Moreover, it is to be understood thatboth the foregoing summary of the invention and the following detaileddescription are exemplary and intended to provide further explanationwithout limiting the scope of the invention as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide a furtherunderstanding of the invention, are incorporated in and constitute apart of this specification, illustrate embodiments of the invention andtogether with the detailed description serve to explain the principlesof the invention. No attempt is made to show structural details of theinvention in more detail than may be necessary for a fundamentalunderstanding of the invention and the various ways in which it may bepracticed. In the drawings:

FIG. 1A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 1B illustrates a frontal view of the embodiment of FIG. 1A;

FIG. 2A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 2B illustrates a frontal view the embodiment of FIG. 2A;

FIG. 3A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 3B illustrates a frontal view the embodiment of FIG. 3A;

FIG. 4A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 4B illustrates a frontal view the embodiment of FIG. 4A;

FIG. 5A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 5B illustrates a frontal view the embodiment of FIG. 5A;

FIG. 6A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 6B illustrates a frontal view the embodiment of FIG. 6A;

FIG. 7A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 7B illustrates a frontal view the embodiment of FIG. 7A;

FIG. 8A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIG. 8B illustrates a frontal view the embodiment of FIG. 8A:

FIG. 9 illustrates a frontal view of an exemplary embodiment of anapparatus, configured according to principles of the invention;

FIGS. 10A-10F each illustrate in perspective a separate exemplaryembodiment of a pin, configured according to principles of theinvention;

FIG. 11A illustrates in top view an exemplary embodiment of an apparatusaccording to the present invention;

FIG. 11B illustrates in frontal view an exemplary embodiment of anapparatus according to the present invention generally corresponding tothe embodiment of FIG. 11A;

FIG. 11C illustrates in bottom view an exemplary embodiment of anapparatus according to the present invention generally corresponding tothe embodiment of FIG. 11A;

FIG. 12 illustrates in frontal view an exemplary embodiment of portionsof an apparatus, constructed according to principles of the invention;

FIG. 13A illustrates in perspective view an exemplary embodiment of apin, configured according to principles of the invention;

FIG. 13B illustrates in perspective view another exemplary embodiment ofa pin, configured according to principles of the invention;

FIG. 14 illustrates in perspective view an exemplary embodiment of anapparatus, configured according to the principles of the invention; and

FIG. 15 illustrates in perspective view an exemplary embodiment of alight assembly, configured according to principles of the invention.

DETAILED DESCRIPTION OF THE INVENTION

The embodiments of the invention and the various features andadvantageous details thereof are explained more fully with reference tothe non-limiting embodiments and examples that are described and/orillustrated in the accompanying drawings and detailed in the followingdescription. It should be noted that the features illustrated in thedrawings are not necessarily drawn to scale, and features of oneembodiment may be employed with other embodiments as the skilled artisanwould recognize, even if not explicitly stated herein. Descriptions ofwell-known components and processing techniques may be omitted so as tonot unnecessarily obscure the embodiments of the invention. The examplesused herein are intended merely to facilitate an understanding of waysin which the invention may be practiced and to further enable those ofskill in the art to practice the embodiments of the invention.Accordingly, the examples and embodiments herein should not be construedas limiting the scope of the invention, which is defined solely by theappended claims and applicable law. Moreover, it is noted that likereference numerals represent similar parts throughout the several viewsof the drawings.

Referring now to the various embodiments of the Figures, in variousaspects, the apparatus 1 may include a printed circuit board (PCB) 10,which defines a first surface 12 and a second surface 14. An electronicspackage 20 may be disposed about the first surface 12 of the PCB 10, andthe electronics package 20 may generate heat. The PCB 10 may include ametal layer 40 and a core 50, and, in some aspects, may include multiplecores 50 interposed between multiple metal layers 40. The metal layer 40may be disposed on a core first surface 52 of the core 50. The metallayer 40 may include metal such as copper, silver, gold, other metal, orother conductive material or combinations thereof suitable to definetraces 70, which are circuit paths for electronic components affixed tothe PCB 10. The core 50 may include any of the well known andelectrically non-conducting materials commonly used in PCB manufacturesuch as FR4. As the core 50 may be electrically non-conducting, the core50 may be thermally insulating, and, accordingly, inhibit the transferof heat from the electronics package 20 through the PCB 10.

The apparatus 1 may include one or more pins 30. Each pin 30 has a firstend 32 and a second end 34, and is formed from heat conductive materialor combinations of heat conductive materials. A plurality of pins 30 maybe disposed about the PCB 10 with first ends 32 generally proximate theelectronics package 20 and configured to conduct at least a portion ofthe heat away from the electronics package 20. The pins 30 may beconfigured with an orientation to pass generally through the PCB 10 fromthe first surface 12 to the second surface 14, with the first ends 32 ofthe pins 30 configured to be positioned generally proximate theelectronics package 20 to provide paths for heat conduction from theelectronics package 20 through the core 50 of the PCB 10. In certainaspects, portions of the pin 30, including the second end 34, may extendgenerally beyond the second surface 14 of the PCB to define an extension36. The extension 36 may disperse or dissipate heat by convection and/orradiation. In such aspects, a plurality of pins 30 may includeextensions 36 to form an array 120 which may further enhance heatdispersal.

In various aspects, the PCB 10 may include a backplane 60 having abackplane first surface 62 generally affixed to the core second surface54 as shown in FIGS. 4B, 5B, 6B, 8B, 9 and 10. The backplane 60 may becomprised of a metal such as copper, aluminum, graphite, otherconductive material, or combinations thereof. The backplane 60 mayfunction, among other things, to provide a common potential forcircuitry attached to the PCB 10 and/or to serve as a heat spreader todiffuse heat generated by the operation of the circuitry attached to thePCB 10 including the electronics package 20. As such, the backplane 60may be electrically conductive and/or may be thermally conductive.

In embodiments of the PCB 10 that include the backplane 60, portions ofthe pins 30 may be configured to extend into at least portions of thebackplane 60 in order to transfer heat from the pins 30 into thebackplane 60 for dispersal. The pins 30 may be configured to extend intothe backplane 60 to secure, at least in part, the backplane 60 to thecore 50. In particular, the backplane 60 may include, at least in part,graphite, and the pins 30 may be configured to secure such a graphitebackplane 60 to the core 50.

Each pin 30 may be a generally elongated member such as a nail, screw,bolt, strip, pin, or the like, and may be configured to conduct heatbetween the first end 32 and the second end 34. Accordingly, each pin 30may be formed of copper, brass, steel, or various other metals, metalalloys, or other heat conductive materials, or combinations thereof. Thepin 30 may have a generally constant cross-section between the first end32 and the second end 34 or may be, at least in part, tapered betweenthe first end 32 and the second end 34. The cross-section of the pin 30may be substantially cylindrical, in some aspects, while, in otheraspects, the pin 30 may have, for example, a polygonal cross-sectionsuch as rectangular or hexagonal cross-section. In still other aspects,the pin 30 may have a star shaped cross-section. In other aspects, thepin 30 may be flattened proximate the second end 34, perhaps enlarged,to provide a relatively larger surface area to increase heatdissipation. A portion of the pin 30, generally proximate the first end32, may form a head 31 that could be, for example, either flat orrounded. A portion of the pin 30, generally proximate the second end 34,may generally define a point 33. In some aspects, the pin 30 may beconfigured to be driven into the PCB 10 by the application of forceabout the first end 32. In other aspects, the pin 30 may include threadsand/or configured to be threadedly received into the PCB 10. In stillother aspects, the pin 30 may be configured to be slidably received in achannel or other aperture associated with the PCB 10. The pin 30 mayhave various geometric configurations, include various materials, andmay be placed in the PCB 10 in various ways as would be recognized bythose of ordinary skill in the art upon review of this disclosure.Combinations of pins 30 having various lengths, materials, and/orgeometries could be used in some aspects.

The extension 36 may extend generally beyond the backplane secondsurface 64 to disperse heat. Heat may be dispersed from the extension 36by free convection and/or forced convection, as well as by radiation. Invarious aspects, a plurality of extended portions 36 may be configuredto form an array 120, and the array 120 may dissipate heat by freeconvection and/or forced convection. In contrast to fins or other suchstructures, air may flow through the array 120 in multiple directions toconvect heat from the array 120. As would be understood by those ofordinary skill in the art upon review of this disclosure, additionalcomponents such as, for example, fins for heat dispersion and structuralmembers may be secured to the backplane second surface 64, and theadditional components may be secured, at least in part, by one or morepins 30. Also, as would be understood by those of ordinary skill in theart upon review of this disclosure, various welds, adhesives, solders,and other mechanisms of attachment may be provided to secure variousportions of the PCB 10 together, so that various adhesive and otherlayers may be interposed between the components in various aspects. Forexample, the core 50 may be adhesively secured to the backplane 60,which may interpose an adhesive layer generally between the core secondsurface 54 and the backplane first surface 62.

FIG. 1A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention, and FIG.1B illustrates a frontal view of the embodiment of FIG. 1A. A PCB 10 mayinclude a metal layer 40 and a core 50. The metal layer first surface 42and portions of the core first surface 52 generally define the firstsurface 12 of the PCB 10, and the second surface 14 of the PCB 10 isgenerally defined by the core second surface 54, as illustrated. Themetal layer 40 may have a second surface 44.

An electronics package 20 having a package first surface 22 and apackage second surface 24 may be disposed about the first surface 12 ofthe PCB 10, as illustrated in FIGS. 1A and 1B, with portions of thepackage second surface 24 biased against portions of the core firstsurface 52. Traces 70 configured from the metal layer 40 may be disposedupon the core first surface 52, and the electronics package 20 may be inelectrical communication with the traces 70 by electrical connectors 72,as illustrated. The electrical connectors 72 may be, for example, powerleads, wire bonds, SMD leads, electrode pads, or the like.

As further illustrated in FIGS. 1A and 1B, pins 30.1, 30.2 may beconfigured to pass through the PCB 10 including the core 50 from thecore first surface 52 to the core second surface 54 to conduct heatgenerated by the electronics package 20, generally from the firstsurface 12 to the second surface 14. The first ends 32.1, 32.2 of pins30.1, 30.2 may be placed proximate the core first surface 52 andproximate the package second surface 24 to receive heat from the packagesecond surface 24 of the electronics package 20. In some embodiments,portions of the first ends 32.1, 32.2 may be generally biased againstthe package second surface 24. The pins 30.1, 30.2 may conduct the heatfrom the first ends 32.1, 32.2 through the core 50 from the core firstsurface 52 to the core second surface 54, and generally to the secondends 34.1, 34.2. As illustrated, portions of the pins 30.1, 30.2,generally proximate the second ends 34.1, 34.2, may protrude generallybeyond the core second surface 54 to define extensions 36.1, 36.2. Atleast some heat conducted through the core 50 from the electronicspackage 20 may be dispersed, at least in part, by convection and/orradiation from the extensions 36.1, 36.2. The extensions 36.1, 36.2 maydefine the array 120, as illustrated. In other embodiments, the secondends 34.1, 34.2 may lie generally between the core first surface 52 andthe core second surface 54, and/or may be generally proximate the coresecond surface 54 to disperse heat from the core second surface 54.

FIG. 2A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention. FIG. 2Billustrates a frontal view of the embodiment of FIG. 2A. In FIGS. 2A and2B, a PCB 10 that includes a metal layer 40 and a core 50 is generallyillustrated. The metal layer 40 may include a first surface 42 andportions of the core first surface 52 may generally define the firstsurface 12 of the PCB 10. The second surface 14 of the PCB 10 may begenerally defined by the core second surface 54, as illustrated.

As illustrated, portions of the metal layer 40 define traces 70. Otherportions of the metal layer 40 may define a pad 80 having a pad firstsurface 82 and a pad second surface 84, with the pad 80 electricallyisolated from the traces 70, as illustrated. The electronics package 20may be disposed about the first surface 12 of the PCB 10, as illustratedin FIGS. 2A and 2B, with portions of the package second surface 24generally abutting portions of the pad first surface 82, so that theelectronics package 20 may be in thermal communication with the pad 80to distribute heat from the electronics package 20 into the pad 80. Theelectronics package 20 may be in electrical communication with thetraces 70 by electrical connectors 72, as illustrated.

As further illustrated in FIGS. 2A and 2B, a plurality of pins 30 may beconfigured to be disposed about the pad 80 to conduct heat from the pad80 through the core 50. The pins 30 may pass through the PCB 10including the pad 80 from the pad first surface 82 to the pad secondsurface 84 and through the core 50 from the core first surface 52 to thecore second surface 54 to conduct heat generally from the first surface12 to the second surface 14. In this implementation, any heat generatedby the electronics package 20 may be conducted from the package secondsurface 24 by the pad 80 and distributed to the pins 30 generallyproximate the first ends 32 of the pins 30. The heat may be conductedthrough the core 50 from the core first surface 52 to the core secondsurface 54 by the pins 30, and the heat dispersed generally from thecore second surface 54. As illustrated, heat conducted through the core50 from the electronics package 20 may be dispersed, at least in part,by convection and/or radiation from the extensions 36 of the pins 30. Invarious implementations, the convective heat transfer from the array 120formed by the extensions 36 may be either non-forced or forced.

In some implementations, at least some pins 30 may pass through the pad80 from the pad first surface 82 to the pad second surface 84, and thefirst ends 32 may be generally proximate the pad first surface 82. Inother implementations, at least some of the first ends 32 of the pins 30may be generally proximate the pad second surface 84. In still otherimplementations, at least some of the first ends 32 of the pins 30 maybe generally biased against the second surface 84 of the pad 80.

FIG. 3A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention. FIG. 3Billustrates a frontal view of the embodiment of FIG. 3A. In FIGS. 3A and3B, a PCB 10 that includes a metal layer 40 and a core 50 is generallyillustrated. The metal layer first surface 42 and portions of the corefirst surface 52 may generally define the first surface 12 of the PCB10. The second surface 14 of the PCB 10 may be generally defined by thecore second surface 54, as illustrated.

Portions of the metal layer 40 may define traces 70, as illustrated.Other portions of the metal layer 40 may define a pad 80 having a padfirst surface 82 and a pad second surface 84, with the pad 80electrically isolated from the traces 70, as illustrated in FIGS. 3A and3B. As illustrated, a heat slug 90 having a first heat slug surface 92and a second heat slug surface 94 may be secured to the pad 80 with thesecond heat slug surface 94 generally abutting the first pad surface 82.In this implementation, the shape of the second heat slug surface 94 maygenerally conform to the shape of the first pad surface 82. Theelectronics package 20 may be disposed about the first surface 12 of thePCB 10, as illustrated, with portions of the package second surface 24biased against portions of the heat slug first surface 82 so that theelectronics package 20 is in thermal communication with the heat slug90, which, in turn, may be in thermal communication with the pad 80 and,thence, with the pins 30 generally proximate the first ends 32. Theelectronics package 20, as illustrated, may be in electricalcommunication with the traces 70 by electrical connectors 72.

As illustrated in FIGS. 3A and 3B, the plurality of pins 30 may bedisposed about the pad 80. The pins 30 pass through the PCB 10 includingthe core 50 generally from the core first surface 52 to the core secondsurface 54 to conduct heat from the first side 12 to the second side 14of the PCB 10. In this implementation, heat generated by the electronicspackage 20 may be conducted from the package second surface 24 throughthe heat slug first surface 94 into the heat slug 90. Heat may beconducted from the heat slug second surface 94 through the pad firstsurface 82 into the pad 80 to generally distribute heat from theelectronics package 20 throughout the heat slug 90 and the pad 80. Heatmay be conducted into the pins 30 generally proximate the first ends 32of the pins 30 from the pad 80 and/or the heat slug 90, and the pins 30may conduct heat through the core 50 from the core first surface 52 tothe core second surface 54 to allow the heat to be dispersed generallyfrom the core second surface 54, which, in this implementation, definesthe second surface 14 of the PCB 10.

In various implementations, the pins 30 may be configured to be inthermal communication with the pad 80 and/or with the heat slug 90 bybeing at least in part positioned proximate the pad 80 and/or heat slug90, by passing through at least a portion of the pad 80 and/or heat slug90, perhaps by being biased against or otherwise in mechanical contactwith or soldered/welded to the pad 80 and/or the heat slug 90, or inother ways as would be readily recognized by those of ordinary skill inthe art upon review of this disclosure, or combinations thereof. Asillustrated in FIGS. 3A and 3B, portions of the pins 30 configured to begenerally proximate the second ends 34 form extensions 36 to disperseheat, at least in part, by convection and/or radiation.

FIGS. 4A and 4B generally illustrate a PCB 10 that includes the metallayer 40, the core 50, and the backplane 60, with the backplane 60comprising a heat conductive material such as, for example, a metal,graphite, or the like. The metal layer first surface 42 and portions ofthe core first surface 52 may be configured to generally define thefirst surface 12 of the PCB 10. The second surface 14 of the PCB 10 maybe generally defined by the backplane second surface 64, as illustrated.

The electronics package 20 may be disposed about the first surface 12 ofthe PCB 10, as illustrated in FIGS. 4A and 4B, with portions of thepackage second surface 24 biased against portions of the core firstsurface 52 or soldered/welded thereto to transfer heat by conductionthrough the package second surface 24 to the core first surface 52. Inother implementations, the package second surface 24 may be generallyset apart, at least in part, from the core first surface 52 so that heatmay be transferred by radiation and/or convection from the packagesecond surface 24 to the core first surface 52. Traces 70 configuredfrom the metal layer 40 may be disposed upon the core first surface 52,and the electronics package 20 may be in electrical communication withthe traces 70 by electrical connectors 72, as illustrated.

The core 50 may be sandwiched between the metal layer 40 and thebackplane 60, as illustrated in FIGS. 4A and 4B. The core 50, which maybe a thermal and electrical insulator, may inhibit conduction of heatemitted by the electronics package 20 to the backplane 60 and, hence,may inhibit the dispersal of heat generated by the electronics package20 from the backplane 60. As illustrated, pins 30 may be configured topass through the core 50 from the core first surface 52 to the coresecond surface 54 and through the backplane 60 from the backplane firstsurface 62 to the backplane second surface 64 and beyond to conduct heatfrom the electronics package 30 to the backplane 60 in order to diffusethe heat generated by the electronics package 20 throughout thebackplane 60. The first ends 32 of the pins 30 may be placed proximatethe package second surface 24 to be in thermal communication with thepackage second surface 24 in order to conduct heat generated by theelectronics package 20 from the package second surface 24 through thecore 50 from the core first surface 52 to the core second surface 54 andinto the backplane 60. The backplane 60 may disperse the heat generallyfrom the backplane second surface 64 by convection and/or radiation orthe like.

As illustrated, portions of the pins 30, generally proximate the secondends 34, may define extensions 36 that protrude generally outward fromthe backplane second surface 64. Heat may be dispersed, at least inpart, by convection and/or radiation from the extensions 36.

FIGS. 5A and 5B generally illustrate a PCB 10 that includes the metallayer 40, the core 50, and the backplane 60. The backplane 60 mayinclude a heat conductive material. Portions of the metal layer 40 maydefine traces 70, as illustrated. Other portions of the metal layer 40may define a pad 80 having a pad first surface 82 and a pad secondsurface 84, with the pad 80 electrically isolated from the traces 70 inthe illustrated implementation. The electronics package 20 may bedisposed about the first surface 12 of the PCB 10, as illustrated inFIGS. 5A and 5B, with portions of the package second surface 24generally abutting portions of the pad first surface 82 so that theelectronics package 20 may be in thermal communication with the pad 80.Accordingly, heat generated by the electronics package 20 may bedistributed throughout the pad 80.

As illustrated, pins 30 may be disposed about the pad 80 to conduct heatfrom the pad 80 through the core 50 and into the backplane 60 in orderto disperse heat generated by the electronics package 20 from thebackplane 60. The first ends 32 of the pins 30, in this implementation,may be located generally about the pad first surface 82 of the pad 80.The pins 30 may pass through the pad 80 generally from the pad firstsurface 82 to the pad second surface 84, through the core 50 from thecore first surface 52 to the core second surface 54 and through thebackplane 60 from the backplane first surface 62 to the backplane secondsurface 64 and extend outward from the backplane second surface 64. Thebackplane 60 may disperse the heat generally from the backplane secondsurface 64 by convection and/or radiation. As illustrated, portions ofthe pins 30, generally proximate the second ends 34, protrude generallybeyond the backplane second surface 64 to form extensions 36. Heat maybe dispersed by convection and/or radiation from the extensions 36. Thepins 30, in various implementations, may secure, or at least aid insecuring, the backplane 60 to the core 50. In implementations whereinthe backplane 60 includes graphite, the pins 30 may be advantageous forsecuring the graphite backplane 60 to the core. In variousimplementations, the pins 30 may have differing lengths. In variousimplementations, the second ends 24 may be configured to terminatewithin the backplane 60, or the second ends 34 of the pins 30 may bebiased against the backplane first surface 62.

FIG. 6A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention. FIG. 6Billustrates a frontal view of the embodiment of FIG. 6A. Theimplementation illustrated in FIGS. 6A and 6B includes a metal layer 40,a core 50, and a backplane 60. The backplane 60 may comprise a heatconductive material. Portions of the metal layer 40 may define traces70, as illustrated, while other portions of the metal layer 40 maydefine the pad 80. The pad 80 may be electrically isolated from thetraces 70. Also, as illustrated in FIGS. 6A and 6B, a heat slug 90having a first heat slug surface 92 and a second heat slug surface 94may be secured to the pad 80 with the second heat slug surface 94generally abutting the first pad surface 82. The electronics package 20may be configured to be disposed about the first surface 12 of the PCB10, as illustrated, with portions of the package second surface 24biased against portions of the heat slug first surface 82 so that theelectronics package 20 may be in thermal communication with the heatslug 90 to distribute heat generated by the electronics package 20throughout the heat slug 90 and pad 80. Pins 30 may pass through the pad80, the core 50, and the backplane 60 to conduct heat generated by theelectronics package 20 from the pad 80 and heat slug 90 to the backplane60 for dispersal. Heat may be dispersed, at least in part, by convectionand/or radiation from the extensions 36 that form array 120 in thisimplementation.

FIG. 7A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention. FIG. 7Billustrates a frontal view of the embodiment of FIG. 7A. In thisimplementation, one or more pins 30 may be configured to pass at leastpartially through the trace(s) 70. As illustrated, the PCB 10 mayinclude the metal layer 40 from which the traces 70 are configured, andthe core 50. Pins 30 may be disposed about the electronics package 20 toconduct heat generated by the electronics package 20 from the firstsurface 12 to the second surface 14 to be dispersed. Pins 30 that passat least partially through the traces 70 may pass at least partiallyinto the core 50. The core 50 may electrically isolate the pins 30 sothat substantially no short circuiting may occur through the core 50between pins 30 when having differing potentials.

In other implementations that include the pad 80, the pad 80 may beelectrically charged in order to supply power to the electronics package20. Pins 30 that may contact the pad 80 in such implementations would beelectrically isolated by the core so that substantially no shortcircuiting occurs through the core 50 between pins 30 when havingdiffering potentials.

FIG. 8A illustrates in plan view an exemplary embodiment of anapparatus, configured according to principles of the invention. FIG. 8Billustrates a frontal view the embodiment of FIG. 8A. One or more pins30 may pass through the trace(s) 70, as illustrated in FIGS. 8A and 8B.Also, as illustrated, the PCB 10 may include the metal layer 40 fromwhich the traces 70 may be configured, the core 50, and the backplane60. Pins 30 may be disposed about the electronics package 20 to conductheat generated by the electronics package from the first surface 12 tothe second surface 14 for dispersal. Pins 30 that pass through thetraces 70 may pass into the core 50. The core 50 may electricallyisolate the pins 30 so that substantially no short circuiting occursthrough the core 50 between pins 30, when they have differingpotentials. As illustrated, the backplane 60 may include backplanecavities 66 that pass about respective pins 30 so that the pins 30 donot contact (i.e., are isolated from) the backplane 60 in order toprevent short circuiting between pins 30 through the backplane 60. Thebackplane cavities 66 may include a non-conducting or insulatingmaterial. The pins 30 may exchange heat with the backplane 60 byradiation and/or convection, and the pins 30 may also generally disperseheat through the portions of the pins 30 proximate the second ends 34 byradiation and/or convection in this implementation.

Because of the backplane cavities 66, the pins 30 do not directlycontact the backplane 60, which may limit the heat conductance betweenthe pins 30 and the backplane 60. In an alternative implementation, thepins 30 may be anodized or chemically treated, at least in part, so thatthe surfaces of the pins 30 are electrically non-conductive. Theanodized pin 30 may pass through the trace 70, through the core 50 andinto the backplane 60, perhaps with mechanical contact between the pins30 and the backplane 60, to conduct heat generated by the electronicspackage from the first surface 12 to the backplane 60 without shortcircuiting. Similarly, in implementations wherein the pad 80 may beelectrically charged, anodized pins 30 may electrically contact the pad80 at the end 32 and contact the backplane 60 without short circuiting.

FIG. 9 illustrates a frontal view of an exemplary embodiment of anapparatus, configured according to principles of the invention. As shownin this implementation, pins 30.1, 30.2 may pass through the PCB 10including the core 50 to conduct heat generated by the electronicspackage 20 generally from the first surface 12 to the second surface 14.The pins 30.1, 30.2 may be configured to be disposed proximate theelectronics package 20 and configured to be in thermal communicationwith the electronics package 20 so that heat generated by theelectronics package 20 may be conducted through the package secondsurface 14 into the pins 30.1, 30.2 generally proximate the first ends32.1, 32.2. The pins 30.1, 30.2 may conduct heat through the core 50from the core first surface 52 to the core second surface 54. The pins30.1, 30.2 may pass through the backplane 60, and heat may be conductedfrom the pins 30.1, 30.2 into the backplane 60. The backplane 60, inthis implementation, may include graphite which conducts heatanisotropically. The preferred directions for heat conduction in thebackplane 60, in this implementation, are parallel to the planes definedby the backplane first surface 62 and the backplane second surface 64.Thus, the backplane 60 may conduct heat from pins 30.1, 30.2, to pins30.3, 30.4, 30.5, and heat may be generally dispersed by convectionand/or radiation from the extensions 36.3, 36.4, 36.5 that protrudebeyond the backplane second surface 64. As illustrated, heat conductedthrough the core 50 from the electronics package 20 may be dispersed, atleast in part, by convection and/or radiation from the extensions 36.1,36.2.

FIGS. 10A-10F each illustrate in perspective view a separate exemplaryembodiment of a pin, configured according to principles of theinvention.

FIG. 10A illustrates a pin 30 configured to have a generally roundedhead 31 at the first end 32. The pin 30 illustrated in FIG. 10B has agenerally flat head 31 at the first end 32 and the second end 34 may beconfigured with a point 33. The pins 30 illustrated in FIGS. 10C, 10D,10E, and 10F have generally square, generally rectangular, hexagonal,and star shaped cross-sections, respectively. The pin 30 may assumeother shapes and configurations as would be recognized by those ofordinary skill in the art upon review of this disclosure.

Methods, in various aspects, may include arranging the apparatus 1, PCB10, metal layer 40, core 50, and/or electronics package 20 with the pins30. Further the method may include generating heat proximate the firstsurface 12 of the PCB 10 by an electronics package 20 and may includeconducting the heat from the first surface 12 to the second surface 14,at least in part, using a plurality of pins 30. The methods may includedispersing heat from an array 120 defined by a plurality of extensions36. The methods may include securing the backplane 60, at least in partby a plurality of pins 30.

In the apparatus described above, the electronics package 20 may includeone or more lighting devices, computing devices, memory storage devices,communication devices, and/or the like. For example, the lightingdevices may include LEDs and any associated electronics.

Further, with respect to the aspects described above, the apparatus 1may be light, a computer, a storage device, a telecommunications deviceor the like, or any combination thereof.

FIGS. 11A, 11B, and 11C illustrate an exemplary implementation that mayinclude a first PCB 210 and a second PCB 220, with the first PCB 210 setapart and secured at an interval 230 from the second PCB 220 by aplurality of pins 30. One or more LEDs 250 may be surface mounted to thefirst PCB first surface 212. The second PCB 220 may be configured toinclude a driver circuit 395 that may provide regulated electrical powerto each of the one or more LEDs 250, in the illustrated exemplaryimplementation. As illustrated, the pins 30 may be disposed about thefirst PCB 210 such that portions of the pins 30, generally proximate thefirst ends 32, may be in thermal communication with the one or more LEDs250 in order to conduct at least a portion of the heat generated by theone or more LEDs 250 through the first PCB 210 from the first PCB firstsurface 212 to the first PCB second surface 214 to disperse the at leasta portion of the generated heat generally away from the first PCB secondsurface 214. The plurality of pins 30 may form an array 260 between thefirst PCB second surface 214 and the second PCB first surface 222through which air flow 397, perhaps including the flow of other heattransfer media, may pass. Heat conducted by the one or more pins 30 fromthe one or more LEDs 250 through the first PCB 210 from the first PCBfirst surface 212 to the first PCB second surface 214 may be dispersedfrom the array 250 by either free or forced convective air flow 397through the array. Heat may also be dispersed from the array 260 byradiation. In some embodiments, the first PCB 210 may have acircumference that mates with a circumference of the housing 380.

FIG. 12 illustrates in frontal view an exemplary embodiment of portionsof an apparatus, constructed according to principles of the invention.As illustrated in FIG. 12, the first PCB 210 may include a first core270 interposed between a first metal layer 280 and a second metal layer290. In this illustrated implementation, a first metal layer secondsurface 284 may be generally biased against a first core first surface272, and a second metal layer first surface 292 may be generally biasedagainst the first core second surface 274 to form the first PCB 210. Aswould be understood by those of ordinary skill in the art upon review ofthis disclosure, various adhesives and other materials may be interposedbetween the first metal layer second surface 284 and the first corefirst surface 272, and/or between the first core second surface 274 andthe second metal layer first surface 292. In other implementations, aswould be recognized by those of ordinary skill in the art upon review ofthis disclosure, the first PCB 210 could include multiple cores withinterposed metal layers. Moreover, in alternate implementations, themetal layer of the embodiments herein might be equivalently implementedby any suitable conducting material, perhaps including a non-metallicmaterial that is suitable to be successfully adapted for applying to thefirst core first surface 272.

First traces 286 configured from the first metal layer 280 may bedisposed upon the first core first surface 272 such that portions of thefirst core first surface 272 and portions of the first metal layer firstsurface 282 define the first PCB first surface 212 as illustrated inFIG. 11A. In various implementations, the first metal layer firstsurface 282 may be covered by a masking material so that the maskingmaterial and/or the first core first surface 272 define the first PCBfirst surface 212. The first metal layer first surface 282 may, invarious implementations, be plated, coated, or otherwise treated, forexample, to prevent oxidation. The LEDs 250, in this implementation, maybe disposed about the first PCB first surface 212 to be in electricalcommunication with the first traces 286.

Similarly, in this exemplary implementation, second traces 296configured from the second metal layer 290 may be disposed upon thefirst core second surface 274 such that portions of the first coresecond surface 274 and portions of the second metal layer second surface294 may define the first PCB second surface 214. In variousimplementations, the second metal layer second surface 294 may becovered by a masking material so that the masking material and/or thefirst core second surface 274 define the first PCB second surface 214.The second traces 296 disposed upon the first core second surface, inthis implementation, mirror the first traces 286 disposed upon the firstcore first surface 272, and the first traces 286 and the second traces296 may be in electrical communication.

As illustrated in FIG. 12, the second PCB 220 may include a second core300 interposed between a third metal layer 310 and a fourth metal layer320. In this illustrated example, a third metal layer second surface 314may be generally biased against the second core first surface 302, and afourth metal layer first surface 322 may be generally biased against thesecond core second surface 304 to form the second PCB 220. As would beunderstood by those of ordinary skill in the art upon review of thisdisclosure, various adhesives and other materials may be interposedbetween the third metal layer second surface 314 and the second corefirst surface 302, and/or between the second core second surface 304 andthe fourth metal layer first surface 322. In other implementations, aswould be recognized by those of ordinary skill in the art upon review ofthis disclosure, the second PCB 220 could include multiple cores withinterposed metal layers.

One or more third traces 316 configured from the third metal layer 310may be disposed upon the second core first surface 302 such thatportions of the second core first surface 302 and portions of the thirdmetal layer first surface 312 define the second PCB first surface 222 inthe illustrated exemplary implementation. In various implementations,the third metal layer first surface 312 may be covered by a maskingmaterial so that the masking material and/or the second core firstsurface 302 define the second PCB first surface 222.

Fourth traces 326 configured from the fourth metal layer 320 may bedisposed upon the second core second surface 304 such that portions ofthe second core second surface 304 and portions of the fourth metallayer second surface 324 may define the second PCB second surface 224.In various implementations, the fourth metal layer second surface 324may be covered by a masking material so that the masking material and/orthe second core second surface 304 may define the second PCB secondsurface 224. One or more of the fourth traces 326 disposed upon thesecond core second surface 304, in this implementation, may be inelectrical communication with one or more of the third traces 316disposed upon the second core first surface 302.

The first core 270 and the second core 300 may comprise an electricallyinsulating material that may also be thermally insulating. Accordingly,the pins 30 may provide a path for efficient heat conduction through thefirst core 270 and/or through the second core 300.

In the illustrated exemplary implementation, a first power connector 342and a second power connector 344 are received into the second PCB 220and extend forth from the second PCB 220 to communicate electric powerfrom a source to the second PCB 220. The second PCB 220 may include adriver circuit 395 configured to receive electric power from the sourceand to provide regulated electric power to the one or more LEDs 250secured to the first PCB 210. The driver circuit 395 may include one ormore electronics packages 346, which may be disposed about the secondPCB first surface 222 and/or the second PCB second surface 224, asillustrated in FIG. 11C.

In the implementations, the first ends 32 of the pins 30 may be receivedin the first PCB 210 and the second ends 34 of the pins 30 may bereceived in the second PCB 220 to secure the first PCB 210 to the secondPCB 220 at the interval 230, as illustrated. Also as illustrated, thefirst ends 32 of the pins 30 may be disposed generally about the firstPCB first surface 212 and the second ends 34 of the pins 30 may bedisposed about the second PCB second surface 224.

The pins 30 may form an array 260 in the interval 230 between the firstPCB second surface 214 and the second PCB first surface 222, and thepins 30 may be set apart such that air flow 397 may pass around andthrough the array 260 to disperse heat from the array 260. Asillustrated in FIG. 11B, the surfaces 35 of adjacent pins 30 may definegap 397, where the gap 397 may be sufficient for air to flow through todisperse heat from the pins 30 by convection.

At least a portion of the pins 30 generally proximate the first ends 32may be in thermal communication with the LEDs 250 in order to conduct aportion of the heat generated by the LEDs 250 from the first PCB firstsurface 212 through the first core 270 to the first PCB second surface214 for dispersal, at least in part, from the array 260. The second ends34 of the pins 30 may, in some implementations, be in thermalcommunication with one or more electronics packages 346 secured to thesecond PCB second surface 224 to conduct at least a portion of the heatgenerated by the electronics packages 346 from the second PCB secondsurface 224 to the second PCB first surface 222 for dispersal from thearray 260. In various implementations, one or more pins 30 may be inthermal communication with one or more electronics packages 346 disposedabout the first PCB second surface 214 and/or disposed about the secondPCB first surface 222 to communicate at least a portion of the heat fromthe one or more electronics packages 346 to the array 260 for dispersal.

As illustrated, a pin 350 may engage a third trace 316 and/or a fourthtrace 326 on the second PCB 220 and may engage a first trace 286 and/ora second trace 296 on the first PCB 210 such that the first PCB 210 andthe second PCB 220 may be in electrical communication. Accordingly, thedriver circuit 395 configured on the second PCB 220 may communicateregulated power, for example, to drive the one or more LEDs 250 attachedto the first PCB 210 through third trace 316 and/or fourth trace 326,through the pin 350 to the first trace 286 and/or second trace 296, and,thence, to one or more LEDs 250.

For example, a first via 360 is defined by a first conductive layer 362and extends from the first PCB first side 212 to the first PCB secondside 214, as illustrated in FIG. 12. The first conductive layer 362 maybe composed of a metal such as copper or other electrically conductivematerial and is configured to place the second trace 296 in electricalcommunication, as illustrated. The first trace 286 and the second trace296 arc in electrical communication with LED 250 through the LEDconnector 251 secured to the first trace 286, as illustrated.

Portions of the pin 350 generally proximate the first pin end 352 arereceived in the first via 360 and secured by solder 364 in thisimplementation. Portions of the pin 350 generally proximate the firstpin end 352 may be “star shaped” or otherwise configured in various waysas would be recognized by those of ordinary skill in the art upon reviewof this disclosure to take up solder. The first trace 286 and the secondtrace 296 may electrically communicate through the pin 350, in thisimplementation, as well as through the first conductive layer 362, andthe first trace 286 and the second trace 296 may electricallycommunicate with the driver circuit 395 on the second PCB 220 throughthe pin 350.

As illustrated in FIG. 12, a second via 361 is defined by a secondconductive layer 363 and extends from the second PCB first side 222 tothe second PCB second side 224. The second conductive layer 363 may becomposed of a metal such as copper or other electrically conductivematerial, and is configured to place the third trace 316 and the fourthtrace 226 in electrical communication, as illustrated. Portions of thepin 350 generally proximate the second pin end 354 are received in thesecond via 361 and secured by solder 364 in this implementation. Thedriver circuit 395 may be in electrical communication with the thirdtrace 316 and/or the fourth trace 326 and, as a consequence, with theLED 250 on the first PCB 210 through the pin 350.

As illustrated in FIGS. 11B and 14, an assembly 370 may include thefirst PCB 210 with one or more LEDs 250 disposed about the first PCBfirst surface 212, the second PCB 220 with the second PCB 220 configuredto include the driver circuit 395, and with the first PCB 210 securablyheld at the interval 230 from the second PCB 220 by a plurality of pins30 that form array 260. The assembly 370 may be positioned in a housing380. The housing 380, in this exemplary implementation, may beconfigured to receive the assembly 370 and to maintain orientation ofthe LEDs 250 in order to direct light emitted from the LEDs 250. Thehousing 380 may define one or more apertures 385, and air flow 397 maypass through the one or more apertures 385, as indicated, either by freeconvection or by forced convection to disperse heat from the array 260.Heat may be dispersed from the array 260 by radiation through the one ormore apertures 385.

The one or more apertures 385 may be disposed circumferentially aboutthe housing 380 such that the air flow 397 may pass through the one ormore apertures 385 and through the array 260 generally normal to an axis392 of the pins 30, as illustrated in FIG. 14. In implementationswherein the pins 30 may be substantially symmetrical about the axis 392,as illustrated in FIG. 13A for example, the pins 30 may be oriented suchthat the axis 392 may be more or less perpendicular to the air flow 397,and the air flow 397 may be at any circumferential orientation withrespect to the axis 392. In other implementations, the pins 30 may have,for example, a generally rectangular configuration, perhaps withincreased surface area, and may be oriented such that the air flow 397may pass generally parallel to the rectangular surface 35, asillustrated in FIG. 13B.

In operation, the one or more LEDs 250 attached to the first PCB firstsurface 212 may generate heat. Pins 30 may thermally communicate withthe one or more LEDs 250 to conduct heat from the one or more LEDsthrough the first PCB 210 from the first PCB first surface 212 to thefirst PCB second surface 214 and to disperse the heat from the array 260in the interval 230 between the first PCB second surface 214 and thesecond PCB first surface 222. In some implementations, air flow 397 maybe provided by forced convection to disperse the heat from the array260, at least in part. In other implementations, air flow 397 by freeconvection may be provided to disperse the heat from the array 260, atleast in part. In various implementations, one or more pins 30 may be inthermal communication with one or more electronics packages 346 securedto the first PCB first surface 212, the first PCB second surface 214,the second PCB first surface 222, and/or the second PCB second surface224 to dissipate heat from the one or more electronics packages 346 fromthe array 260 in the interval 230. In various implementations, thedriver circuit 395 may be configured onto the second PCB 220 and mayelectrically communicate with one or more LEDs 250 on the first PCB, atleast in part, by one or more pins 350.

Methods, in various aspects, may include generating heat proximate thefirst surface 12 of the PCB 10 by an electronics package 20 and mayinclude conducting the heat from the first surface 12 to the secondsurface 14, at least in part, using a plurality of pins 30. The methodsmay include dispersing heat from any array 120 defined by a plurality ofextensions 36. The methods may include securing the backplane 60, atleast in part, by a plurality of pins 30.

In the apparatus described above, the one or more electronics packagesmay include one or more lighting devices, computing devices, memorystorage devices, communication devices, and/or the like. For example,the lighting devices may be LEDs and any associated electronics.Further, with respect to the aspects described above, the assembly 370may include a light, a computer, a storage device, a telecommunicationsdevice or the like, or any combination thereof.

FIG. 15 illustrates in perspective view an exemplary embodiment of alight assembly, configured according to principles of the invention. Inparticular, FIG. 15 shows a light assembly 382 that includes housing 380having a housing first end and a housing second end and arranged arounda central axis 440, substantially internal electrical components such asassembly 370, and an illumination end 390. In different applications,the light assembly 382 may include, but not limited to, any embodimentof FIGS. 1-14 herein. The light assembly 382 may be configured toreceive an electrical component assembly (e.g., assembly 370) generallywithin and/or substantially enveloped by the housing 380. However,certain portions of the electrical component assembly may be external tothe housing, such as portions of power connectors 342, 344 (shown inFIG. 14), for example.

The housing 380 may orient an electrical connector for receivingexternal power, such as configured to include a standard screw typeelectrical connection 410, similar to incandescent type bulbs. Othertypes of connections for other light arrangements are contemplated.

The housing 380 may also include a slotted, or fin 420 type construction(such as, e.g., to create the one or more apertures 385 shown in FIG.14) that allows air flow, generally to a volume of space generallywithin the housing 380, and in particular, to and past the pins 30,which may be arranged to form an array 260, for venting generated heatout of the housing 380. The housing 380 may be formed of any materialincluding synthetic materials such as plastic. The housing 380 may beconfigured to include a plurality of openings 430 (or vents) about thecircumference of the housing 380.

The plurality of openings 430 may be defined by a plurality of fins 420.The fins 420 may have a first fin end and a second fin end and may beconfigured to provide structural integrity to the housing by connectinga first portion of the light assembly proximate the illumination end 390to a second portion proximate the electrical connection 410. Each of thefins 420 may have a curvature extending from each fin second end suchthat the plurality of fins 420 converge towards the central axis 440proximate each fin first end. The fin first end may be proximate ormerge with a common portion 445 of the housing. The plurality of fins420 may be configured to form a plurality of vents therebetween. Theplurality of fins 420 may be shaped in a curved fashion from the firstportion towards the second portion. The curvature of the plurality offins 420 may extend from proximate the illumination end 390, i.e.,housing first end, for a length approximately half the total length (alength measured from the housing first end 404 to the housing second end406) of the housing 380, and may merge and converge and at a commonportion 445 of the housing 380. The plurality of fins may be arrangedaround the central axis 440.

In one aspect, the curvatures of the fins 420 may aid to impart anoverall visual form of the light assembly 382 that generally resemblesor mimics a shape related to common flood or spot lights, for example.The overall shape of the housing may mimic or resemble a PAR 30 or a PAR38 light. The housing 380 may have a circumference larger at a housingfirst end 404 greater than a housing second end 406. A circumference ofthe housing at approximately the mid-point 407 of the length of thehousing may be less than that circumference at the first end 404, butgreater than the circumference proximate the housing second end 406. Thehousing first end 404 may be proximate the illumination end 390. Thehousing first end 404 may be configured to include a ring portion 412 inhousing 380 such that a spacing 413 may be formed between the ringportion 412 and an illumination portion 411 of the illumination end 390by the plurality of fins 420. The circumference of the ring portion 412may be more than twice the circumference of the housing 380 proximatethe second end 406.

The illumination portion 411 may be mated with an inner housing portion414 that may be formed in a polygonal shape, but any suitable shape maybe employed that substantially matches with the shape of theillumination portion 411. The circumference of illumination portion 411may substantially match or align in close proximity with thecircumference of the inner housing portion 411.

In some embodiments, a circumference at one end of the housing 380, suchas end proximate the first PCB 210 (FIG. 11B) or proximate the housingfirst end 404, may be configured to be in contact with a circumferenceof one of the PCBs (e.g., PCB 210) of assembly 370 (FIG. 11B). Forexample, a circumferential edge of PCB 210 may mate, or align in closeproximity, with an internal circumference at an end of the housing 380.An endpiece 450 proximate the housing second end 406 may and arrangedproximate to an end of each fin. The endpiece 450 may have a continuouscircumference about the central axis 440. An electrical connector 410may be arranged proximate the endpiece 450 and along the central axis440. A space may be provided arranged along the central axis 440proximate the housing second end 406 and further configured with theplurality of fins and the plurality of vents arranged therearound. Thespace configured, at least in part, to accept or house a light assembly.

In some applications, the light assembly 382 may be covered by aseparate face-plate cover (not shown) on the illumination end 390 toassist in repulsing environmental elements and/or aid in focusingemitted light. Although, the lights of the invention are well-suited aslight sources for homes and businesses (i.e., for producing visiblewhite light), such as shown in FIG. 15, the embodiments of the inventionmay be also well-suited as light sources for computer monitors, TVs,video displays, projectors, and the like.

In accordance with various embodiments of the invention, the methodsdescribed herein are intended for operation with dedicated hardwareimplementations including, but not limited to, semiconductors,application specific integrated circuits, programmable logic arrays, andother hardware devices constructed to implement the methods and modulesdescribed herein.

While the invention has been described in terms of exemplaryembodiments, those skilled in the art will recognize that the inventioncan be practiced with modifications in the spirit and scope of theappended claims. These examples given above are merely illustrative andare not meant to be an exhaustive list of all possible designs,embodiments, applications or modifications of the invention.

1. An apparatus for a light assembly comprising: a housing comprising ahousing first end and a housing second end arranged along a centralaxis, the housing further comprising: a plurality of fins each having afin first end and a fin second end, the plurality of fins forming aplurality of vents therebetween and defining a plurality of apertures ina wall of the housing, each the plurality of fins has a curvatureextending from the fin second end such that the plurality of finsconverge towards the central axis proximate each fin first end, a widthof each formed vent being greater then a width of each fin forming arespective vent; an endpiece proximate the housing first end andarranged proximate to the fin first end of each of the plurality offins, the endpiece having a circular portion comprising a continuouscircumference about the central axis; an electrical connector arrangedproximate to the endpiece and arranged along the central axis; and aspace arranged along the central axis proximate the housing second endand further configured with the plurality of fins and the plurality ofvents arranged therearound, the space configured to, at least in part,house a light assembly.
 2. The apparatus of claim 1, wherein theplurality of fins are configured to form a parabolic shape, at least inpart.
 3. The apparatus of claim 2, wherein the vents are arrangedproximate an electronic heat generating source within the space and thevents are configured to provide venting of the generated heat.
 4. Theapparatus of claim 2, wherein the plurality of fins converge and mergewith a common portion of the housing about midway along an overalllength of the housing.
 5. The apparatus of claim 1, wherein the housingforms a shape similar to at least one of a PAR 30 or a PAR 38 light. 6.The apparatus of claim 1, wherein the light assembly is configured toemit light out of the housing second end.
 7. The apparatus of claim 6,wherein the light assembly includes one or more light emitting diodes(LED).
 8. The apparatus of claim 1, wherein at least a portion of thehousing is formed of a synthetic material.
 9. The apparatus of claim 1,wherein at least a portion of the plurality of fins is formed of asynthetic material.
 10. The apparatus of claim 1, wherein each fin hasan outer edge and further comprising a ring configured around the outeredge proximate each fin second end forming an outermost circumference ofthe housing and the ring having the largest circumference of thehousing.
 11. A light assembly apparatus comprising: a housing comprisinga housing first end and a housing second end arranged along a centralaxis, the housing further comprising: a plurality of fins each having afin first end and a fin second end, the plurality of fins forming aplurality of vents therebetween and defining a plurality of apertures ina wall of the housing, each the plurality of fins being arrangedsubstantially symmetrically about the central axis, a distance betweenadjacent fins changing dimension along a length of the adjacent fins; anendpiece proximate the housing first end and arranged proximate to thefin first end of each of the plurality of fins, the endpiece having acircular portion comprising a continuous circumference about the centralaxis; an electrical connector arranged proximate to the endpiece andarranged along the central axis; and a space arranged along the centralaxis proximate the housing second end and further configured with theplurality of fins and the plurality of vents arranged therearound, thespace configured to, at least in part, house a light assembly.
 12. Theapparatus of claim 11, wherein the plurality of fins are configured toform a parabolic shape, at least in part.
 13. The apparatus of claim 12,wherein the vents are arranged proximate an electronic heat generatingsource within the space and the vents are configured to provide ventingof the generated heat.
 14. The apparatus of claim 12, wherein theplurality of fins converge and merge with a common portion of thehousing about midway along an overall length of the housing.
 15. Theapparatus of claim 11, wherein the housing forms a shape similar to atleast one of a PAR 30 or a PAR 38 light.
 16. The apparatus of claim 11,wherein the light assembly is configured to emit light out of thehousing second end.
 17. The apparatus of claim 16, wherein the lightassembly includes one or more light emitting diodes (LED).
 18. Theapparatus of claim 11, wherein at least a portion of the housing isformed of a synthetic material.
 19. The apparatus of claim 11, whereinat least a portion of the plurality of fins is formed of a syntheticmaterial.
 20. The apparatus of claim 11, further comprising a ringportion proximate the housing second end, the ring portion having acontinuous circumference about the central axis and the ring portionbeing attached to the plurality of fins at the fin second end to spacethe plurality of fins to form the vents.
 21. The apparatus of claim 11,wherein each fin has an outer surface and further comprising a ringconfigured around the outer surface proximate each fin second end andforming an outermost circumference of the housing and the ring havingthe largest circumference of the housing.
 22. A method for configuring alight assembly, the method comprising the steps of; providing a housinghaving a first end and a housing second end and arranged along a centralaxis; providing a plurality of fins each having a fin first end and afin second end, the plurality of fins forming a plurality of ventstherebetween and defining at least one aperture in a wall of thehousing, each the plurality of fins has a curvature extending from thefin second end such that the plurality of fins converge towards thecentral axis proximate each fin first end, a width between adjacent finschanging dimension along a length of the adjacent fins; providing anendpiece proximate the housing first end and arranged proximate to thefin first end of each of the plurality of fins, the endpiece having acircular portion comprising a continuous circumference about the centralaxis; providing an electrical connector arranged proximate to theendpiece; and providing a space arranged along the central axisproximate the housing second end and further configured with theplurality of fins and the plurality of vents arranged therearound, thespace configured to, at least in part, house a light assembly.
 23. Amethod for configuring a light assembly, the method comprising the stepsof; constructing a plurality of fins each having a fin first end and afin second end, the plurality of fins forming a plurality of ventstherebetween and defining at least one aperture in a wall of thehousing, each of the plurality of fins having a curvature extending fromthe fin second end such that the plurality of fins converge towards acentral axis proximate each fin first end, a width between adjacent finschanging dimension along a length of the adjacent fins, the plurality offins arranged in a circumferential manner to form part of a housingincluding forming a space therewithin along the central axis; forming anendpiece proximate to the fin first end of each of the plurality offins, the endpiece having a circular portion comprising a continuouscircumference about the central axis, the endpiece having an electricalconnector configured therein, the endpiece forming a part of thehousing; mating a printed circuit board (PCB) having at least one lightemitting diode to the housing thereby creating a light assembly withinthe housing, so that the plurality of vents vent heat generated out ofthe housing and the electrical connector is configured to provide powerto the PCB, wherein the an overall shape of the plurality of fins andthe endpiece mimic a shape of a PAR 30 or PAR 38 light.